Article

Received 30.01.2025

Revised 26.05.2025

Accepted 24.06.2025

Retrieved from Iss. 117, P. 2, 2025

Pages 199 -205

Mamonov, K., Afanasiev, O., Vyatkin, R., & Frolov, V. (2025). FORMATION OF METROLOGICAL SUPPORT OF GEODESICAL ACTIVITIES. Automobile Roads and Road Construction, (117.2), 199-205. https://doi.org/10.33744/0365-8171-2025-117.2-199-205

FORMATION OF METROLOGICAL SUPPORT OF GEODESICAL ACTIVITIES

Kostiantyn Mamonov Oleksandr Afanasiev Roman Vyatkin Viacheslav Frolov

It was determined that the formation of metrological support for geodetic activities is an important component that affects the quality and completeness of spatial support for territorial development of land use. The creation of metrological support in the field of geodetic activities is a complex multifaceted process that includes instrumental, technological, technical components. As a result of the study, the goal of determining the directions and features of the formation of metrological support for geodetic activities was achieved. To achieve the set goal, the following tasks were solved: characterization of the directions of formation of metrological support for geodetic activities; identification of factors that influence the formation of metrological support for geodetic activities. Metrological support for geodetic activities is defined as a system of measurements using technological, technical, organizational, informational, metrological norms and rules aimed at achieving completeness and quality of measurements with geodetic tools for the formation of spatial support for territorial development of land use.
The definition of metrological support of geodetic activity is proposed, which is based on its system parameters, features of its formation and application. The features of the formation of metrological support of geodetic activity are identified, which are determined by the influence of functional, organizational, stakeholder, technical, technological factors. Metrological support affects the quality of geodetic work, which is aimed at increasing the completeness of spatial support in the system of territorial development of land use

metrological support, geodetic activities, factors of formation of metrological support, spatial support, territorial development of land use
  1. Kaminskyi, V.Yu., & Mamovyk, K.M. (2010). Methodology for synthesizing an autonomous metrological support system for nuclear power plants. Collection of Scientific Works of the National University of Nuclear Power Engineering and Industry, 161-168.
  2. Mykyichuk, M.M., & Stoliarchuk, P.H. (2011). Generalized mathematical model of the efficiency of the production metrological support system. Ukrainian Metrological Journal, 4, 3-7.
  3. Mykyichuk, M.M., Ohirko, R.M., & Boiko, T.H. (2004). Forecasting errors of industrial temperature measuring instruments. Automation, Measurement and Control. Bulletin of Lviv Polytechnic National University, 500, 36-40.
  4. Ohirko, R.M., & Mykyichuk, M.M. (2002). Principles of constructing universal measuring instruments for process automation. Measurement Engineering and Metrology, 59, 145-156.
  5. Mykyichuk, M.M., & Stoliarchuk, P.H. (2011). Increasing the metrological autonomy of industrial measurements. Metrology and Instruments, 3, 43-47.
  6. Mykyichuk, M.M., & Stoliarchuk, P.H. (2011). Increasing the metrological autonomy of local measurement systems. Collection of Scientific Works of Kharkiv University of the Air Force, 1(27), 222-225.
  7. Mykyichuk, M., Stoliarchuk, P., & Bubela, T. (2017). Main tasks and features of metrological support for product quality. Retrieved from https://science.lpnu.ua/sites/default/files/journalpaper/2017/jun/3848/vtm74st20.pdf.
  8. Volodarskyi, Ye.T., Kukharčuk, V.V., Podzharenko, V.O., & Serdiuk, H.B. (2001). Metrological support of measurements and control: Textbook. Vinnytsia: Vinnytsia State Technical University. 
  9. Kononov, V.B., & Burtseva, V.V. (2017). Mathematical models for determining the number of orders for guaranteed metrological maintenance of samples of weapons and military equipment taking into account their importance. Information Processing Systems, 1(147), 88-92.
  10. Kononov, V.B., Naumenko, A.M., Vodolazhko, O.V., Koval, O.V., & Kondrashova, I.I. (2017). Fundamentals of operation of measuring instruments of military purpose in the conditions of the anti-terrorist operation. Kharkiv: Kharkiv National University of the Air Force.
  11. Kuchuk, H.A. (2007). Traffic management of a multiservice distributed telecommunication network. Control Systems, Navigation and Communication, 2, 18-27. Kyiv: Central Research Institute of the National University.
  12. Kononov, V.B., Naumenko, A.M., & Koval, O.V. (2018). Application of electrical measurements by measuring instruments in the conditions of the anti-terrorist operation: Textbook. Kharkiv: Kharkiv National University of the Air Force.
  13. Kuchuk, H.A., Kovalenko, A.A., & Lukova-Chuiko, N.V. (2017). Method for minimizing the average packet delay in virtual connections of a cloud service support network. Control Systems, Navigation and Communication, 2(42), 117-120.
  14. Kuznetsov, I.B., Martsenkivskyi, V.T., Yaroshenko, O.V., Buyalo, O.V., & Protsenko, V.O. (2011). Improvement of the fleet of mobile measuring laboratories as a factor in increasing the efficiency and effectiveness of metrological maintenance of complex systems. Collection of Scientific Works of Kyiv National University, 32, 33-46.
  15. Verkhovna Rada of Ukraine. (2014). Law of Ukraine "On Metrology and Metrological Activity" (No. 1314-VII, as amended on November 15, 2024). Retrieved from https://zakon.rada.gov.ua/laws/show/1314-18#Text.
  16. Cabinet of Ministers of Ukraine. (2016). On approval of the Technical Regulation on measuring instruments (Resolution No. 163, as amended on September 27, 2024). Retrieved from https://zakon.rada.gov.ua/laws/show/163-2016-п#Text.

https://doi.org/10.33744/0365-8171-2025-117.2-199-205